KR100352477B1 - Air conditioner - Google Patents

Abstract

The present invention relates to an air conditioner, and in particular, to improve the structure of the condensate receiver, the evaporator rear cover, the evaporator upper cover, and to facilitate the manufacturing and assembly work, and to reduce the manufacturing cost.

In the air conditioner according to the present invention, an air conditioner including an evaporator installed in the interior of the main body and a condensate receiver coupled to a lower portion of the evaporator and having a drainage groove for discharging the collected condensate, the condensate receiver is injected. It is formed integrally with the rear cover installed on the rear side of the evaporator through molding, and the drain groove of the condensate receiver is provided with a groove member extending rearward to guide the condensate backward, so that the groove member penetrates back and forth through the bottom of the duct. It is coupled to the formed condensate guide groove.

Description

Air Conditioner {AIR CONDITIONER}

The present invention relates to an air conditioner, and more particularly, to an air conditioner having an improved condensate receiver and a drainage structure of the condensate receiver.

In general, as shown in FIG. 1, a window type air conditioner has a suction port 2 and a discharge port 3 for suction and discharge of indoor air in front of the main body 1, and the rear of the main body 1. The suction port 4 and the discharge port (not shown) are formed in the suction and discharge of the outdoor air. Further, inside the indoor air intake port 2, an evaporator 5 for heat exchange of indoor air and an evaporator fan 6 for blowing air heat exchanged in the evaporator 5 toward the discharge port 3 are provided.

In addition, a duct 7 is formed around the evaporator fan 6 to form a flow path for guiding the blown air toward the discharge port 3, and an evaporator (2) is provided to partition the space where the evaporator 5 is installed and the discharged flow path. 5) The rear cover and the upper cover (8) and the upper cover (9) are installed. And the lower part of the evaporator (5) is provided with a condensate receiver 10 for collecting and discharging the condensate flowing down from the evaporator (5).

The condensate receiver 10 is formed with an overflow prevention jaw 10a at the rim so that the condensed water flows down to the center portion, and the bottom surface has a downward slope from both ends to the center. In addition, a drainage groove 10b is formed at the rear side of the condensate receiver 10 so that the collected condensate is discharged to the rear side.

In addition, the condensate receiver 10 is made of Styropor material, which is usually a heat insulating material, in order to prevent dew condensation of the interior bottom plate 11, and drains the bottom surface of the condensate receiver 10 coupled with the bottom plate 11. An adhesive sealing member (not shown) has been attached so that the condensed water discharged through the groove 10b does not flow to the lower side of the condensate receiver 10. This is to prevent dew condensation on the inner surface of the bottom plate 11 due to cold condensate.

However, the conventional air conditioner of such a configuration is that the condensate receiver 10 is made of styropole material, so that the rigidity is weak and not only damaged by a small impact in the process of installing it, but also to attach a sealing member (not shown) to the bottom during installation. There was a complicated problem of assembly work.

In addition, the conventional air conditioner weakens the adhesive force of the sealing member attached to the lower part of the condensate receiver 10 when used for a long time, so that the cold condensate discharged through the drain groove 10b, that is, the indoor side of the bottom plate 11, that is, the condensate receiver ( 10) there was a problem flowing into the lower portion, due to this problem there was a problem that dew condensation occurs on the outer surface of the indoor bottom plate (11).

The present invention is to solve such problems, it is an object of the present invention to provide an air conditioner to improve the rigidity, manufacturability and mounting of the condensate receiver through the structural improvement of the condensate receiver.

In addition, another object of the present invention is to improve the structure of the drain groove of the condensate receiver to prevent the condensate discharged into the interior bottom plate to provide an air conditioner to prevent dew condensation on the interior bottom plate.

1 is an exploded perspective view showing the internal configuration of a conventional air conditioner.

Figure 2 is an exploded perspective view showing the internal configuration of the air conditioner according to the present invention.

Figure 3 is a perspective view showing the configuration of the evaporator rear cover and the top cover, and the condensate receiver of the air conditioner according to the present invention.

4 is a perspective view showing the condensate receiving groove member and the condensate guide groove of the duct of the air conditioner according to the present invention.

5 is a cross-sectional view showing a coupling structure of the condensate receiver, the rear cover, the upper cover, the duct of the air conditioner according to the present invention.

Explanation of symbols on the main parts of the drawings

20: main body, 21: upper case,

22: bottom plate, 23: front panel,

27: evaporator, 28: evaporator fan,

30: duct, 31: condensate guide groove,

41: rear cover, 42: top cover,

44,45a: bending groove, 45: connecting member,

46: coupling groove, 50: condensate receiver,

54: drain groove, 55: groove member.

An air conditioner according to the present invention for achieving the above object, the evaporator is installed on the interior side of the main body, the condensate receiver is coupled to the lower portion of the evaporator and formed with a drain groove for discharging the condensate collected, the indoor air An air conditioner including an evaporator fan disposed behind the evaporator to circulate, and a duct installed around the evaporator fan to form a discharge flow path, the air conditioner comprising: a predetermined length protruding from the drain groove of the condensate receiver toward the rear of the main body; And a condensate guide groove formed in the duct so as to guide the condensate discharged through the groove member to the rear of the main body, and the groove member fitted therein.

In addition, a rear cover is provided at the rear of the evaporator, and the condensate receiver provided with the groove member is manufactured integrally with the rear cover through injection molding, and the condensate receiver is refractively connected to the rear cover.

Hereinafter, with reference to the accompanying drawings a preferred embodiment according to the present invention will be described in detail.

As shown in FIG. 2 and FIG. 3, the air conditioner according to the present invention forms a skeleton of the main body 20, and includes an upper case 21, a bottom plate 22, and an upper surface and both sides thereof integrally formed. A front panel 23 and a rear panel (not shown) are provided. At this time, the front panel 23 side of the main body 20 is disposed on the indoor side of the building, the rear panel side is disposed on the outdoor side of the building.

An indoor air suction port 24 and an indoor air discharge port 25 for suctioning and discharging indoor air are formed in the front panel 23 on the indoor side, and the upper and side surfaces of the upper case 21 on the outdoor side allow suction of external air. The outside air suction port 26 is formed. And although not shown, the air outlet is formed on the rear panel.

In addition, an evaporator 27 is installed inside the indoor air inlet 24 of the front panel 23 to generate cold air by heat-exchanging the indoor air, and an evaporator fan 28 for suctioning indoor air to the rear of the evaporator 27. ) Is installed. In addition, a duct 30 is formed around the evaporator fan 28 to form a flow path for guiding the blown air toward the discharge port 25, and the inner space of the main body 20 is located at the rear of the duct 30. The partition plate 32 which partitions to an outdoor side is provided.

In addition, the rear cover 41 and the upper cover 42 of the evaporator 27 are installed at the rear and the upper portion of the evaporator 27 so as to partition the space where the evaporator 27 is installed and the discharge passage. And the lower part of the evaporator 27 is provided with a condensate receiver 50 for collecting and discharging the condensate flowing down from the evaporator 27.

In addition, a condenser 33 and a condenser fan 34 for heat exchange and circulation of outside air are installed in the outdoor side of the main body 20, and the evaporator fan 28 and the condenser fan (rear side) adjacent to the partition plate 32 ( A motor 35 for driving 34 and a compressor 36 for compressing the circulating refrigerant to high temperature and high pressure are provided. And behind the control unit 23a of the front panel 23, on which the adjustment knob 37 is installed, a control box 38 having various electric components for starting and operation control of the air conditioner is installed.

Meanwhile, in the air conditioner of the present invention, as illustrated in FIGS. 3 and 4, the condensate receiver 50, the rear cover 41, and the upper cover 42 which are installed around the evaporator 27 are manufactured and installed. In order to facilitate the condensate receiving 50, the rear cover 41, the upper cover 42 is characterized in that the plastic injection molding is integrally manufactured.

In this case, a through hole 41a is formed in the center of the rear cover 41 so that the indoor air heat-exchanged with the evaporator 27 flows toward the evaporator fan 27, and the support of the rigid reinforcement and the evaporator 27 is supported at both ends. Reinforcing ribs 41b are formed.

The condensate receiver 50 is formed with a overflow prevention jaw 51 having a predetermined height extending upwardly so that the condensate flowing down from the evaporator 27 is collected and discharged, and the bottom surface 51 is inclined toward the center from both ends. Is formed. In addition, the bottom surface 51 is formed with an evaporator support portion 53 protruding upward so that the bottom of the evaporator 27 is supported in a state spaced apart from the bottom surface 51, overflowing the central portion and the rear side of the evaporator support portion 53 The prevention jaw 52 is formed with a drain groove 54 for discharging condensate. And the top of the rear side overflow prevention jaw 52 is integrally connected with the bottom of the rear cover 41 of the evaporator 27. At this time, the bent groove 44 of a predetermined depth is formed in the portion where the upper end of the overflow preventing jaw 52 and the lower end of the rear cover 41 are connected to the condensate receiver 50 when the rear cover 41 and the condensate receiver 50 are installed. It is configured to bend.

In addition, the drain groove 54 of the condensate receiver 50 is provided with a groove member 55 extending a predetermined length rearward so that the condensed water accumulated in the condensate receiver 50 can be discharged toward the rear side of the main body 20. At this time, the groove member 55 is formed to be integral with the condensate receiver 50 through the injection molding in the process of manufacturing the rear cover 41 and the condensate receiver 50.

And the lower end of the duct 30 coupled to the rear of the rear cover 41 is provided with a condensate guide groove 31 formed through the front and rear so that the condensate discharged along the groove member 55 is guided to the rear, the condensate guide The groove member 55 is fitted into the groove 31 to be coupled. To this end, the inner surface width of the condensate guide groove 31 is configured to correspond to the outer surface width of the groove member 55.

In addition, the upper cover 42 covering the upper end of the evaporator 27 is connected to the rear cover 41 and the bendable connecting member 45 in a state spaced apart from the predetermined interval. At this time, the connecting member 45 is provided with the same material as the upper cover 42 and the rear cover 41, and is formed integrally with the two covers when forming the upper cover 42 and the rear cover 41. In addition, after the evaporator 27 is installed in the connecting member 45, a portion of the bent groove 45a having a predetermined depth and a portion connected to the upper cover 42 and the rear cover 41 so as to fold the upper cover 42 are provided. Is formed. And the upper end of the rear cover 41 is formed with a coupling groove 46 of a predetermined depth is formed long in the horizontal direction so that the upper cover 42 is fitted in the bent state.

When assembling the air conditioner of this configuration, as shown in Figure 5, the condensate tray 50 and the rear cover 41 in the state of bending the connection portion of the rear cover 41 and the condensate receiver 50, the main body ( 20). At this time, when the condensate receiver 50 is bent, the groove member 55 of the condensate receiver 50 protrudes to the rear, and the groove member 55 protruding rearward is inserted into the condensate guide groove 31 of the duct 30. Combine. In this state, the evaporator 27 is seated on the upper part of the condensate receiver 50, and the upper cover 42 connected to the upper part of the rear cover 41 is bent to cover the upper part of the evaporator 27. In addition, the rear end of the upper cover 42 is fitted into the coupling groove 46 of the top of the rear cover 41 to be coupled.

The air conditioner of this configuration is because the condensate flowing from the evaporator 27 is guided to the rear of the main body 20 through the groove member 55 of the condensate receiver 50 and the condensate guide groove 31 of the duct 30. Condensate can be prevented from flowing to the lower side of the condensate receiver 50 without a separate sealing member. In addition, it is possible to prevent dew formation on the outer surface of the interior bottom plate 22 through this.

As described in detail above, the air conditioner according to the present invention is produced through the injection molding the condensate receiver is integrally with the rear cover and the top cover of the evaporator, and each connecting portion is refractedly connected, the production of the condensate receiver Not only is easy and rigidity greatly improved, there is an effect of easy assembly.

In addition, since the discharged condensate is guided backward through the condensate receiving groove member and the condensate guide groove of the duct, condensate does not flow to the interior bottom plate even without a separate sealing member, so that dew condensation occurs on the interior bottom plate. There is an effect that can prevent.

Claims (2)

An evaporator installed in the interior of the main body, a condensate receiver coupled to a lower part of the evaporator, and having a drain groove for discharging the condensate collected therein, an evaporator fan disposed at the rear of the evaporator to circulate indoor air, and a discharge; An air conditioner comprising a duct installed around the evaporator fan to form a flow path, A groove member extending from the drain groove of the condensate receiver toward the rear of the main body and a condensate formed in the duct to guide the condensate discharged through the groove member to the rear of the main body; Air conditioner comprising a guide groove. The method of claim 1, The rear cover is provided on the rear of the evaporator, The condensate receiver provided with the groove member is manufactured integrally with the rear cover through injection molding, wherein the condensate receiver is refractively connected to the rear cover.